state-of-the-art restorations
TRANSCRIPT
State-of-the-art restorationsfor posterior teeth
Tetric EvoCeram® Bulk Fill
Spec
ial E
dit
ion
Prof. Dr Jürgen Manhart Prof. Dr Dipl.-Ing. Nicoleta Ilie
Ever since composite-based restorative materials gained acceptance as a standard means of restoring load bearing
posterior teeth, efforts have been underway to improve and further develop these materials and the associated
adhesive systems and polymerization equipment. At the same time, the indication range of c omposite materials
has gradually increased as a result of extensive clinical research studies. The results of these investigations have
led to the introduction of effective modifications in clinical applications and in treatment protocols.
The introduction of bulk-fill composites, which offer improved depth of cure, represents a further milestone in
the development of adhesive dentistry. These materials are already proving to be very popular among dental
practitioners. With these new light-curing composites, large cavities can be restored using only a few incre-
ments, adding a new dimension to the direct adhesive technique in posterior teeth. In short, they offer an effi-
cient, state-of-the-art, economical solution for restoring posterior teeth.
Ivoclar Vivadent introduced a material of this kind in 2011: Tetric EvoCeram Bulk Fill. In terms of its formulation,
the product is closely related to the hybrid composite Tetric EvoCeram, which has firmly established itself in
dental practices over the past decade. As a result of the favourable clinical performance of Tetric EvoCeram in
posterior dentition, similar results can be expected for the bulk-fill version.
Summary
Prof. Dr Jürgen Manhart
Department of Restorative Dentistry
Ludwig-Maximilians University
Goethestraße 70, 80336 Munich, Germany
Prof. Dr Dipl.-Ing. Nicoleta Ilie
Department of Restorative Dentistry
Ludwig-Maximilians University
Goethestr 70, 80336 Munich, Germany
Con
tent
s
State-of-the-art posterior restorations with Tetric EvoCeram® Bulk Fill
1. Long-term performance of composites in posterior teeth 4
2. Clinical aspects of the bulk-fill technique
2.1 Conventional incremental layering technique 6
2.2 Demand for alternative composite resin application protocols 6
2.3 General information about bulk-fill composites 6
Case 1: Large two-surface restoration in an upper molar 9
2.4 Bulk-fill composites at a glance 16
3. Materials science aspects
3.1 Physical properties of dental composites: Correlation between
laboratory results and clinical performance 20
3.2 Materials science of bulk-fill composites 22
3.3 Light transmission of bulk-fill composites 26
3.4 How much light do bulk-fill composites need to polymerize adequately? 28
4. Clinical data
4.1 Published clinical studies 30
Case 2: Replacement of an amalgam restoration in an upper molar 31
4.2 Comparison of Tetric EvoCeram Bulk Fill with other Ivoclar Vivadent composites 39
5. Indication spectrum of bulk-fill composites in permanent and deciduous dentition 40
Case 3: Replacement of a ceramic inlay in a lower molar 41
6. Outlook 49
Case 4: Replacement of two insufficient restorations in the lower posterior dentition 51
7. Literature 60
Ongoing scientific dental research together with the
introduction of completely new restorative materials
and the continuous further development of existing
materials is bringing about many changes to dental
treatment approaches. These advances are also
significantly influencing the life span of dental
restorations [90]. Within the past three decades major
changes have taken place in the way in which
restorative materials are handled [50, 53, 91]. In
addition, the esthetic standards of posterior tooth
restorations have risen considerably [13].
Composite resin restorations have shown to be a
viable and esthetic alternative to metal-based
restorations over the past thirty years [67]. These
materials have evolved quite substantially over the
past decade. The initial clinical data on posterior
composite restoratives in the 1980s were rather
discouraging due to inadequate mechanical properties
in particular. Low wear resistance led to the loss of
restoration contours in quite a short time. Fractures,
marginal cracking and leakage and the associated
staining, secondary caries and hypersensitivity due to
polymerization shrinkage additionally limited the life
span of restorations [42, 70, 73, 77, 109]. However,
these shortcomings have been greatly reduced as
a result of advances made in the development of
composite resins and adhesive systems in the past
years [35, 80].
In the meantime, direct composite restorations have
become an integral component of the treatment
spectrum of modern conservative dentistry. They are
very popular due to their wide range of application
and their tooth preserving nature (defect-oriented
cavity design) and the support of the tooth structure
provided by adhesive bonding. [29,86]. Moreover,
these restorations are much more affordable
compared with indirect alternatives (inlays, partial
crowns, full crowns) and they require less time to
place [54]. Composite resin restorations are also quite
easy to repair within the oral cavity, if the need should
arise [52].
State-of-the-art posterior restorations
with Tetric EvoCeram® Bulk Fill
4
1. Long-term performance of composites in
posterior teeth
Table 1: Annual failure rate (AFR in %) of different types of restorations.Superscripts identify statistically different groups [83].
The results of a comprehensive review of clinical
studies involving various types of posterior tooth
restorations in adult patients has shown that the
annual failure rate (AFR) of composite resin (AFR =
2.2%) today is not statistically significant compared
with that of amalgam (AFR = 3%), which currently
sets the standard for clinical longevity [83]. The results
of the survey of the annual failure rate of various
restorative materials and restoration types are listed in
Table 1[83]. A comparison of the data shows that
composite restorations can actually compete with
indirect restorations, provided they are placed
accurately and within the range of correct indications.
Furthermore, in a long-term clinical study involving
1,202 amalgam and 747 composite restorations in
large Class II cavities, OPDAM reported that composite
restorations showed significantly better performance
than amalgam restorations after 12 years in situ, with
an annual failure rate of 1.68% (amalgam AFR =
2.41% [99]. After a very long observation period of
22 years, DA ROSA RODOLPHO determined
an excellent AFR of 1.5% and 2.2% for two differently
filled hybrid composites (77 vs 57 vol%). Nevertheless,
in the second half of the study period, the annual
failure rate of the lower filled material increased from
1.5% to 2.2%, while that of the higher filled
composite remained constant [26].
Due to the decline in popularity of amalgam through-
out the world, direct composite resins stand a good
chance of replacing amalgam as the most widely used
restorative materials in the near future [29]. Correctly
placed adhesive composite restorations show out-
standing clinical survival rates [29]. Consequently,
they have firmly established themselves in the field of
restorative dentistry.
Amalgam
Composite inlays
Direct composites
Ceramic inlays
CEREC inlays
Gold inlays
0-7,0
0-10,0
0-9,0
0-7,5
0-5,6
0-5,9
3,0 (1,9) C
2,9 (2,6) BC
2,2 (2,0) ABC
1,9 (1,8) AB
1,7 (1,6) A
1,4 (1,4) A
Type of restoration Range Mean value (standard deviation)
5
2.1 Conventional incremental layering
technique
To date, incremental layering is considered to be the
gold standard for placing light-curing composite
materials [102]. Generally, conventional composites
are placed in individual layers of maximum 2 mm
thickness due to their particular polymerization
properties and limited depth of cure. The increments
are individually light polymerized for 10 to 40 s,
depending on the light intensity of the curing light
used and the colour and translucency level of the
corresponding composite paste [64]. Thicker layers
of these regular composites, however, do not poly-
merize properly and therefore produce poor
mechanical and biological properties [18, 37, 118].
The incremental technique allows the individual
composite layers to be favourably oriented within
the cavity, which lowers the C-factor (configuration
factor = number of bonded to unbonded composite
surfaces). This minimizes the material's intrinsic
polymerization induced shrinkage and the related
negative effects on the restoration [34, 118]: e.g.
debonding of the composite from the cavity walls,
marginal leakage and staining, secondary caries,
enamel fractures, cusp deflection, crack formation in
the cusps and hypersensitivity.
2.2 Demand for alternative composite resin
application protocols
The conventional increment technique can be very
time-consuming and complicated when it is used to
fill large and voluminous cavities in posterior teeth.
As a result, many dentists eagerly anticipated the
arrival of an alternative to this highly technique
sensitive multiple layering technique. The main aim
of the development efforts was to a find a way of
placing composites efficiently and with enhanced
reliability. The bulk-fill composites have been
developed in response to this growing demand for
more efficiency. These materials can be placed in
increments of 4 to5 mm thickness [25, 39, 81, 82].
The following factors can help to speed up the
placement of light-curing composite restorations in
posterior teeth and therefore make this procedure
more economical:
• Universal shade of the restorative material ➔
Elimination of complicated and time-consuming
shade selection
• Enhanced translucency of the composite ➔
Increased depth of cure per layer,
therefore, fewer increments
• Optimization of the photo-initiator system of the
light-curing composite ➔ Shorter curing times and
increased depth of cure
• Low-shrinkage composite resisns with minimal
stress build-up ➔ Thicker layers,
therefore, fewer increments
• High-performance polymerization lights ➔ Shorter
and more intensive light polymerization
• Efficient creation of functional occlusal surfaces ➔
Faster finishing and polishing
2.3 General information about bulk-fill
composites
Special composite resins are now available for the
bulk-fill technique. They can be placed more easily
and efficiently due to the fact that they require
less time to polymerize than other composites at
correspondingly higher light intensities (usually
≥ 800 – 1,000 mW/cm²) and have a high depth of cure
(4 – 5 mm increment thickness) (e.g. Tetric EvoCeram
Bulk Fill, Ivoclar Vivadent; QuiXfil, Dentsply; x-tra fil,
Voco; SonicFill, Kerr). The first bulk-fill composites to
be supplied to the market were delivered in a high-
viscosity, sculptable consistency (QuiXfil, Dentsply;
2. Clinical aspects of the bulk-fill technique
6
x-tra fil, Voco). These materials have been available
for more than a decade (market launch of QuiXfil in
2003). However, despite their enhanced depth of
cure, they were unable to establish themselves
successfully on the market [118]. It took another few
years and the launch of the first flowable bulk-fill
composite (SDR, Dentsply) in 2009 before the demand
for these materials would grow dramatically. This
paved the way for the introduction of additional
products (in high-viscosity and flowable form). The
characteristics required of a bulk-fill composite are
summarized below:
• Extensive and reliable depth of cure
• Low polymerization shrinkage (volumetric
shrinkage in %) and low shrinkage stress
(polymerization contraction stress in MPa) [31, 127].
• Excellent adaptation of the material to the
cavity margins and walls/floor
• Appropriate physical and mechanical
properties (flexural strength, fracture toughness
KIC, modulus of elasticity, Vickers hardness, etc.) also
in deep cavities/thick increments
• Sufficient wear resistance
• Sufficient working time for clinical application and
occlusal moulding (of highly viscous materials)
• Sufficient radiopacity
The bulk-fill composites are specially engineered to
meet the above requirements. Both polymerization
shrinkage and shrinkage stress have a major influence
on the quality of the margins of composite-based
restorations [110]. To this end, special monomers or
fillers have been added to the bulk-fill composites,
which reduce the shrinkage stress during
polymization: The modulus of elasticity rises slowly
during the curing phase, without detrimentally affecting
the polymerization rate and the final degree of poly -
merization (an adequately high conversion rate is
important for achieving good mechanical and biological
material properties) [15, 31, 46, 59, 119, 126]. Apart
from the traditional glass fillers, Tetric EvoCeram Bulk
fill contains a shrinkage stress reliever in the form of a
patented, special filler (prepolymer), whose modulus
of elasticity is relatively low at 10 GPa (by comparison:
the modulus of elasticity of glass fillers is approx.
71 GPa). This filler acts like a microscopic spring and
absorbs the stresses generated during light activation
[120].
Bulk-fill composites are generally more translucent
than conventional composites (shade and translucency
level influence the depth of cure of composites) in
order to ensure sufficient light polymerization of thick
restoration layers. Nevertheless, individual products can
differ quite considerably in this respect [12, 33, 57].
This provides a partial explanation for why thick
increments of some bulk-fill composites cure just as
effectively as thin two-millimetre layers of conventional
composites. The elevated level of translucency of
these materials may compromise the esthetic
appearance of the restoration to a certain extent.
However, the issue of esthetics is usually not important
in posterior teeth [71]. On the one hand, high
translucency of a composite may cause a restoration
to look slighly greyish [15]. On the other hand, if the
tooth structure has dark stains, the material may not
provide adequate masking properties. This effect has
to be taken into consideration, e.g. on the mesial
surfaces of premolars [33, 51].
7
When 4-mm thick composite layers are light
polymerized, considerably fewer photons penetrate to
the cavity floor or the bottom of the increment than
originally reached the restoration surface, since the
light rays are scattered by the filler particles and
absorbed by the colour pigments. Advanced, highly
sensitive and reactive light initiator systems (e.g.
Ivocerin in Tetric EvoCeram Bulk Fill, Ivoclar Vivadent),
therefore, provide the second part of the explanation
for the enhanced curing depth of bulk-fill composites.
In addition to the popular initiators such as camphor-
quinone and acyl phosphine oxide, Tetric EvoCeram
Bulk Fill also contains a new highly sensitive light
initiator system (Ivocerin). This innovative polymeriza-
tion booster, which is based on dibenzoyl germanium
derivatives, features an absorption spectrum similar to
that of the widely used camphorquinone. However, it
shows improved quantum efficiency due to its higher
light absorption rate in the visible wavelength range
and therefore higher light-reactivity [94]. As a result,
even very little light (photons) can trigger polymeriza-
tion and achieve a high depth of cure [15, 94].
High-performance lights with an intensity of at least
1,000 mW/cm2 should be used to polymerize bulk-fill
composites (e.g. Bluephase Style from Ivoclar Vivadent).
This will ensure a high conversion rate throughout the
entire increment. Moreover, the final restoration will
exhibit good mechanical and biological properties
(tissue compatibility) – even if the light guide could not
be optimally focused on the composite: for example, if
the tooth is difficult to reach or the distance between
the light guide and the composite surface is very large,
or if a divergent radiation angle is involved. Generally,
bulk-fill composites take 10 s to cure per 4-mm
increment. In contrast to some of the considerably
translucent bulk-fill composites, Tetric EvoCeram Bulk
Fill is slightly more opaque with an enamel-like
translucency. This appearance is achieved as a result of
the high quantum efficiency of the photo-initiator
Ivocerin, which in combination with the coordinated
light refraction index of the fillers (mixed oxides, glass
fillers, radiopaque agents) and the polymer matrix
produces excellent light-optical properties, which
match those of dental hard tissue (enamel in particular)
[93, 120]. The three shades (IVA, IVB, IVW) in which
Tetric EvoCeram Bulk Fill is supplied are more than
adequate for creating virtually invisible restorations in
posterior teeth with normally coloured dentin.
"Bulk Fill" means that a cavity can be filled completely
in a single step according to state-of-the-art
restorative techniques, without having to place
multiple layers [51]. To date, the only direct filling
materials available for this type of application have
been cements and chemically or dual-curing core
build-up composites. Nevertheless: Cements are not
suitable for placing clinically durable restorations in
load-bearing posterior teeth, since their mechanical
properties are inadequate for this indication. There-
fore, cements should only be used for temporary
fillings/long-term temporaries [45].
Moreover, core build-up composites are not approved
for use as restorative materials and they are not
suitable for this purpose due to their specific handling
properties (e.g. lack of sculptability for the design of
the occlusal surface anatomy). Even amalgam has to
be placed in the cavity in increments, which then have
to be condensed individually. Technically, the present
bulk-fill composites that are available for the simplified
restoration of posterior teeth are not really bulk-fill
materials, because many proximal cavities extend into
areas that are deeper than the maximum curing depth
of these materials (4 – 5 mm) [44, 46]. Nonetheless, if
a suitable composite is used, cavities with a depth of
up to 8 mm – which includes most of the cavities seen
on a daily basis in dental clinics – can be restored with
two increments.
8
9
Figure 1
First upper molar with a provisional seal
after endodontic treatment
Case 1:
Large two-surface restoration in an
upper molar
In this first case, a large restoration was placed with
Tetric EvoCeram Bulk Fill. When it was finished, the
restoration was virtually indistinguishable from the
natural tooth structure.
Initial situation
10
Figure 4
The adhesive was air-thinned
until a glossy immobile film formed.
Figure 2
The old filling was removed and
the root canal openings were covered
with glass ionomer cement.
Figure 3
A dry working field was created with a rubber dam,
and the cavity was separated using a sectional matrix.
Then, the tooth structure was conditioned with
Adhese® Universal according to the self-etch technique
(reaction time 20 s).
11
Figure 6
Application of the first layer of
Tetric EvoCeram Bulk Fill
in the mesial box
Figure 5
Light polymerization of the
adhesive for 10 s with Bluephase Style
Figure 7
The composite was moulded with a microbrush,
and the mesial cavity wall was contoured
up to the marginal ridge.
12
Figure 10
Sculpting of the
mesio-palatal cusp
Figure 8
Completed mesial wall
Figure 9
Light polymerization of the composite
for 10 s with Bluephase Style
13
Figure 12
Sculpting of the
disto-buccal cusp
Figure 13
Sculpting of the
disto-palatal cusp
Figure 11
Sculpting of the
mesio-buccal cusp
Figure 14
Due to the wide diameter of the Bluephase Style
light guide, all the occlusal composite increments
could be polymerized simultaneously for 10 s.
14
Figure 15
The matrix was removed and
the restoration was checked for any irregularities.
Figure 16
Finished and high-gloss polished restoration.
The tooth has regained its original appearance and function.
15
Initial situation
Final situation
16
Flowable bulk-fill composites (low viscosity)
Sculptable bulk-fill composites (high viscosity)
SDR (Smart Dentin Replacement)
x-tra base
Venus Bulk Fill
Filtek Bulk FillFlowable Restorative
Beautifil-BulkFlowable
Tetric EvoCeram Bulk Fill
QuiXfil
x-tra fil
SonicFill
everX Posterior
Beautifil-BulkRestorative
Dentsply DeTrey
Voco
Heraeus Kulzer
3M Espe
Shofu Dental
Ivoclar Vivadent
Dentsply DeTrey
Voco
Kerr + KaVo
GC
Shofu Dental
Yes
Yes
Yes
Yes
Yes
No
No
No
No
Yes
No
4 mm
4 mm
4 mm
4 mm
4 mm
4 mm
4 mm
4 mm
5 mm
4 mm
4 mm
Modified UDMA, TEGDMA, EBPDMA
Bis-GMA, UDMA
UDMA, EBPDMA
Bis-GMA, UDMA, Bis-EMA, Procrylate resins
Bis-GMA, UDMA, Bis-MPEPP, TEGDMA
Bis-GMA, Bis-EMA, UDMA
Bis-EMA, UDMA, TEGDMA,TMPTMA, TCB resin
Bis-GMA, UDMA, TEGDMA
Bis-GMA, TEGDMA, EBPDMA
Bis-GMA, PMMA, TEGDMA
Bis-GMA, UDMA, Bis-MPEPP, TEGDMA
Manufacturer Cappinglayernecessary
Max. increment thickness
Organic matrix
Table 2: Bulk-fill composites for posterior teeth (abbreviations: Bis-EMA = ethoxylated bisphenol A dimethacrylate; Bis-GMA = bisphenol A glycidyl methacrylate; UDMA = urethane dimethacrylate; TEGDMA = triethylene glycol dimethacrylate;
Material
2.4 Bulk-fill composites at a glance
17
Flowable bulk-fill composites (low viscosity)
Sculptable bulk-fill composites (high viscosity)
Ba-Al-F-B-Si glass,Sr-Al-F-Si glass
Ba-Al-F-Si glass,ytterbium trifluoride, SiO2
ZrO2/SiO2, ytterbium trifluoride
F-B-Al-Si glass
Ba-Al-Si glass, ytterbium trifluo-ride, spherical mixed oxide,prepolymers
Fine and coarse glass particles
SiO2, glass, oxides
E-glass fibres, Ba glass, SiO2
F-B-Al-Si glass
ZrO2/SiO2:0.01-3.5 µm (average size 0.6 µm); YbF3: 0.1-3.5 µm
64.5/ 42.5
Average size: 4.2 µm 68/45
75/-
0.02-5 µm 65/38
60/-
Particle size of inorganic fillers: 0.04-3 µm, aver-age size 0.55 µm
76-77/ 53-54
Fine glass, average size = 1 µm; coarse glass, average size = 10 µm
86/66
86/70.1
83.5/-
Fibres of 1.3 - 2 mm 74.2/53.6
70/-
Particle size Filler particles wt%/vol%
Remarks Organic matrix
2-mm capping layer made of methacrylate-based posterior hybrid composite is necessary, 1 shade (Universal), 20 s polymerization with light intensity of ≥ 550 mW/cm²
Sculptable nanohybrid composite, 3 universal shades (IVA, IVB, IVW), 10 – 20 s polymerization, dependent on the light intensity used: 10 s polymerization at light intensity of ≥ 1,000 mW/cm², 20 s polymerization at light intensity of ≥ 500 mW/cm²
Sculptable hybrid composite, 1 universal shade, 10 – 20 s poly-merization, dependent on the light intensity used: 20 s polymerization at light intensity of 500-800 mW/cm², 10 s polymerization at light intensity of ≥ 800 mW/cm²
The occlusal surfaces and outer walls of restorations made of this composite containing glass-fibre reinforcement always have to be covered with a methacrylate-based posterior hybrid composite layer of 1 to 2-mm thickness (to achieve a wear resistant and polishable restoration surface), 1 universal shade, 10 – 20 s polymerization, depending on the light intensity used: 20 s polymerization at light intensity of 700 mW/cm², 10 s polymerization at light intensity of ≥ 1,200 mW/cm²
Sculptable hybrid composite, 1 universal shade, 10 – 20 s poly-merization, dependent on the light intensity used: 20 s poly-merization at light intensity of 500 – 800 mW/cm², 10 s poly-merization at light intensity of ≥ 800 mW/cm²
Sculptable hybrid composite, 2 shades (Universal, A), 10 – 20 s polymerization, dependent on the light intensity used: 20 s at light intensity of ≥ 500 mW/cm²; 10 s polymerization at light intensity of ≥ 1,000 mW/cm²
Sculptable nanohybrid composite, 4 shades (A1, A2, A3, B1), extra activation handpiece is needed (KaVo SONICfill, KaVo) ➔ thixotropic effect (temporary change in viscosity from sculptable to flowable through sonic activation with SONICfill activation handpiece), 20 s polymerization at light intensity of ≥ 500 mW/cm²
2-mm capping layer made of methacrylate-based posterior hybrid composite is necessary, 1 shade (Universal), 20 s polymerization with light intensity of ≥ 550 mW/cm²
2-mm capping layer made of methacrylate-based posterior hybrid composite is necessasry, 2 shades (Universal, Dentin), 10 – 40 s polymerization, dependent on the light intensity and the shade used: shade Universal: 20 s polymerization at light intensity of ≥ 500 mW/cm², 10 s at light intenisty ≥ 1,000 mW/cm²; shade Dentin: 40 s at light intensity ≥ 500 mW/cm², 20 s at light intensity ≥ 1,000 mW/cm²
2-mm capping layer made of methacrylate-based posterior hybrid composite is necessary, 4 shades (Universal, A1, A2, A3), 10 – 40 s polymerization, dependent on the light intensity and the shade used: shade Universal: 20 s polymerization at light intensity of 550 – 1,000 mW/cm², 10 s at light intensity of ≥ 1,000 mW/cm²; shades A1-A3: 40 s at light intensity of 550 – 1,000 mW/cm²,20 s at light intensity of ≥ 1,000 mW/cm²
2-mm capping layer made of methacrylate-based posterior hybrid composite is necessary, 2 shades (Universal, A2), 10 – 40 s poly-merization depending on the light intensity and shade used: shade Universal:10 s polymerization at light intensity of ≥ 500 mW/cm²; shade A2: 40 s at light intensity of 500 – 800 mW/cm², 20 s at a light intensit of ≥ 800 mW/cm²
EBPDMA = ethoxylated bisphenol A dimethacrylate, TMPTMA = trimethylolpropane trimethacrylate, PMMA = polymethyl methacrylateTCB resin = butane 1,2,3,4 tetracarbon acid bis-2-hydroxyethyl methacrylate resin, bis-MPEPP = bisphenol A polyethoxy dimethacrylate)
Inorganicfillers
The category of bulk-fill composites is divided into
two subgroups, which demand different application
techniques:
1. Low-viscosity, flowable bulk-fill composites
(Table 3) that need to be protected by an additional
occlusal capping layer made of a regular hybrid
composite [60]. These bulk-fill composites have a low
filler content and contain comparatively large fillers in
order to lower the polymerization stress. As a result,
however, they have poorer mechanical and esthetic
properties compared with conventional hybrid
composites: for example, lower elastic modulus and
wear resistance and increased surface roughness and
inferior polishability [23, 24, 51, 57, 64, 105]. In addition,
the capping layer allows the occlusal surface to be
functionally contoured, as this would be very difficult
or even impossible to manage with a flowable material.
2. Regular to high-viscosity, sculptable bulk-fill
composites (Table 4) that can be used up to the
occlusal surface. They do not require a protective
capping layer. Thus, no additional composite material
is required.
Both types of bulk-fill composite cannot be cured in
layers that are thicker than 4 mm (SonicFill: max. 5 mm
➔ manufacturer's claim). In other words, only the
high-viscosity variants can be regarded as true bulk-fill
materials when they can be placed at a cavity depth,
which corresponds to the maximum depth of cure of
the material. If deeper lesions are involved or if flowable
bulk-fill composites are used, an additional capping
layer will always be necessary.
18
No additional occlusal capping layer is needed ➔ true one-layer technique in cavities of up to 4 mm
Wetting ability/excellent adaptation to cavity walls and all internal line and point angles [46]
Only one composite material is needed to place a restoration
Self-levelling effect as a result of the flowable consistency
The first increment does not have to be manually adapted (it is simply injected) ➔ no packing instruments are needed
The first layer has to be carefully adapted to the cavity walls and all internal line and point angles using a hand instrument
A 2-mm thick capping layer consisting of a conventional methacrylate-based posterior hybrid composite has to be placed on
the flowable bulk-fill composite in order to achieve the required mechanical strength, wear resistance, clinical stability, occlusal
contour and esthetic properties [57, 64, 111, 113].
In the treatment of upper posterior teeth, flowable bulk-fill composite may leak into the distal cavity area or out of the cavity
altogether ➔ Consequently, there is a risk that the required 2-mm capping layer of posterior composite cannot be applied
properly or that the flowable bulk-fill composite has to be cut back in a time-consuming process.
The occlusal anatomy is easy to sculpt due to the firm consistency of the material
The first flowable increment is quickly placed ➔ highly efficient [76]
No additional flowable composite is needed as a liner
High translucency may impair the esthetic properties
High translucency may compromise the esthetic appearance (material forms the occlusal surface)
19
Advantages
Advantages
Disadvantages
Disadvantages
Table 3: Advantages and disadvantages of low-viscosity flowable bulk-fill composites
Table 4: Advantages and disadvantages of high-viscosity sculptable bulk-fill composites
Regular to high-viscosity, sculptable bulk-fill composites
Low-viscosity flowable bulk-fill composites
3. Materials science aspects
3.1 Physical properties of dental composites:
Correlation between laboratory results and
clinical behaviour
It is very costly and time-consuming to perform clinical
evaluations of restorative materials. Since the number
of different composite resins has grown immensely,
most individual materials can no longer be directly
compared in clinical studies. Therefore, the demand
for laboratory investigations is growing in order to
predict the clinical behaviour of materials efficiently
and accurately. However, it is impossible to foresee
the actual performance of an individual material on
the basis of the composite category to which it
belongs, since the mechanical properties vary quite
considerably within these groups [58, 61].
A number of correlations have been found between
the clinical behaviour of bulk-fill composites and their
physical properties measured in the laboratory. But,
the overall clinical performance of composites depends
on many different factors. Therefore, it is impossible
to accurately predict their clinical behaviour by simply
running a few in vitro tests [28, 36]. The clinical success
of a restorative material is determined by a complex
network of influences: they include the material
composition (determined by the manufacturer), the
operator (handling of the material by the dental
practitioner) and the patient [83] (Table 5).
Studies performed to date have established a correla-
tion between the clinical wear of composites and
their flexural strength, the fracture toughness, the
primary particle size and the monomer conversion
rate. Interactions have also been determined between
the marginal integrity of restorations and their
fracture toughness. Furthermore, it is assumed that
the fracture risk and wear rate of a composite
restoration is related to the fatigue resistance of the
material. However, the margin quality and bond
strength of restorations established in the laboratory
show only little correlation with the actual clinical
performance of a composite [36].
Long-term studies on the clinical behaviour of com-
posite materials indicate that today's restorations, in
contrast to those of the past, fail not only primarily
due to secondary caries, but also a rise in material
fractures [26, 29, 49, 121, 124, 125]. The reason for
20
these failures is manifold and includes the fact that
the indications of composites have been extended to
include large Class II cavities. In addition, their
mechanical properties have tended to decline,
especially with regard to the modulus of elasticity, due
to the reduction in size of the filler particles in order to
meet today's esthetic requirements [35, 58]. A
material with a low modulus of elasticity is more
prone to deformation. This is particularly the case
with composite restoratives when they are used in
load-bearing areas (e.g. in posterior teeth). Ultimately,
this shortcoming could result in the fracture of the
restoration. What is more, a restorative material with
a low modulus of elasticity provides less support for
the remaining thin cavity walls of the tooth. There-
fore, more stress is placed on the adhesive interface
and the risk of tooth fractures and marginal defects
increases.
Table 5: Factors that influence the clinical life of dental restorations [83].
Strength (fractures)
Fatigue / Degradation
Bond strength, marginal seal, polymeriza-tion shrinkage, postoperative sensitivity
Wear resistance (OCA, CFA)
Chemical compatibility of therestorative system (adhesive, composite)
Technique sensitivity
Caries inhibiting effects
Correct indication
Cavity preparation (size, type, finish)
Polymerization (device, time,light sensitivity)
Handling and application (e.g. incre-mental layering technique)
Type of finishing and polishing of the restoration
Proper occlusion
Experience (with materials and applica-tion protocols) and care
Oral hygiene,diet
Preventive measures, fluoride
Oral situation (quality of the tooth structure, saliva, etc.) and systemic diseases
Compliance/Recall
Lesion (size, shape, location) and tooth (number of surfaces, vital vs devitalized, premolar vs molar)
Compliance during the treatment
Bruxism, parafunctions, habits
21
Material Dentist Patient
3.2 Materials science of bulk-fill composites
In terms of their chemical composition bulk-fill
composites do not really represent a new category of
materials. They are actually very similar to hybrid
composites. They contain an organic matrix com-
posed of common monomer systems, such as Bis-
GMA (bisphenol A glycidyl methacrylate), EBPDMA
(ethoxylated bisphenol A dimethacrylate), UDMA
(urethane dimethacrylate) and TEGDMA (triethylene
glycol dimethacrylate), in addition to well-known
inorganic fillers [61, 64].
The different application techniques (with or without
an occlusal capping layer) of the bulk-fill composites
are determined by the significantly inferior mechanical
properties of the low-viscosity bulk-fill materials (Table
6). The two types of bulk-fill composites show
considerable differences in their modulus of elasticity.
The modulus of elasticity of highly viscous bulk-fill
composites is very similar to that of microhybrid
composites and significantly higher than that of other
composite types. Flowable bulk-fill composites and
flowable regular composites exhibit statistically similar
values and the lowest modulus of elasticity of the
examined materials categories. Nanohybrid composites
are some where in the medium range. In the micro-
mechanical Vickers hardness test, highly viscous bulk-
fill composites show the highest values, followed by
nano hybrid and microhybrid composites, while the
low- viscosity bulk-fill composites exhibit significantly
lower hardness values than flowable regular
composites (Table 6). It is important to note that the
Vickers hardness of most composite materials is similar
to that of human dentin. However, it is considerably
lower than that of human enamel. The difference
between low-viscosity and high-viscosity bulk-fill
composites is more distinct in the microscopic than in
the macroscopic range, with the Vickers hardness being
more than twice as high in high-viscosity compared
with low-viscosity bulk-fill composite materials.
The statistical evaluation of the filler content reveals
that high-viscosity bulk-fill composites have the highest
values and the low-viscosity bulk-fill composites show
the lowest values of all composite types examined
(Table 6), which corresponds to the measured
mechanical properties.
22
The depth of cure of bulk-fill composites is enhanced
over that of conventional composites mostly by in-
creasing the translucency of the materials [57]. This is
achieved by matching the refractive index of the fillers
to that of the polymer matrix and by varying the filler
content and the size of the filler particles [57], since a
linear correlation between the translucency of a com-
posite and its filler content is known to exist [72].
Under otherwise identical conditions, a lower amount
of filler will produce a more translucent product with
a higher depth of cure. Low-viscosity bulk-fill
composites contain a considerably smaller amount of
fillers in comparison with conventional nonhybrid and
microhybrid composites (Table 6) [64]. Furthermore,
many of the bulk-fill materials (x-tra fil, x-tra base,
SDR, SonicFill) feature much larger fillers (≥ 20 µm)
than regular composite resins [57]. Compared with
the smaller fillers, the same amount (wt%) of these
larger particles significantly reduces the overall surface
area of the filler and therefore the interface between
the inorganic fillers and the organic matrix. Since the
larger filler particles reduce the number of transitions
where light can pass between the matrix and the
fillers, less light can escape and more photons, which
activate the light-sensitive initiator system, can
penetrate the material and thereby increase the depth
of cure of bulk-fill composites [57]. In composites
containing small fillers below the visible light range
(380 – 780 nm), light is neither scattered nor absorbed
by the small particles. This increases the translucency
of the composite as well as the ability to sufficiently
polymerize deep areas of the restoration [68, 89].
However, a low filler content and comparatively large
filler particles compromise the mechanical and
esthetic properties of the material. In addition, they
lower the composite's wear resistance and increase its
surface roughness and impair its polishing properties
[23, 24, 51, 57, 64, 105].
Table 6: Comparison of the mechanical properties of different types of composites (Data from [57] and the latest evaluations based on the data compiled by Prof. Dr Ilie, Munich Dental Clinic). Three-point bending strength (σ), elastic modulus (Emodulus) and Vickers hardness (HV). The filler content is expressed in volume percent (vol%) and weight percent (wt%). Superscripts identify significant subgroups (Tukey’s HSD Test, α = 0.05). The Vickers hardness (VH) test involved a direct comparison with human enamel and dentin (HV).
Microhybrid
Type of composite
131,2BC (29,8)
σ (MPa)
7,3c (2,6)
Emodulus (GPa)
87,0c (28,8) 62,8B (12,5) 78,5b (4,0)
HV (N/mm²)Filler particlesvol%
Filler particleswt%
Nanohybrid 121,9AB (32,6) 5,9b (2,1) 90,9c (35,6) 63,8AB (8,7) 78,2b (7,9)
Low-viscosity bulk-fill 128,4ABC (12,7) 4,7a (1,1) 53,0a (19,2) 46,0D (8,0) 68,1d (3,8)
High-viscosity bulk-fill 135,0C (17,3) 7,4c (2,4) 105,0d (31,5) 65,5A (4,5) 83,4a (2,9)
Flowable 119,3A (25,8) 4,2a (1,3) 65,8b (28,9) 51,1C (10,6) 69,9c (8,2)
Dentin 58,3 (16,0)
Enamel 407,1 (100,0)
23
Due to an advanced photo-initiator, which is extremely
sensitive to incoming photons, Tetric EvoCeram Bulk
Fill offers the 4-mm depth of cure that is characteristic
of bulk-fill composites even though the material is
highly filled with small particles (Table 2).
Flexural strength is a significant parameter in load-
bearing restorations. Commercially available bulk-fill
composites exhibit flexural strength values between
120.8 MPa and 142.8 MPa [57]. This corresponds to
the average flexural strength of nanohybrid and
microhybrid composites [57, 58, 64] and by far
exceeds ISO 4049 [2] of 2009, which establishes a
minimum of 80 MPa.
The restorative technique with flowable bulk-fill
composites and the polymerization shrinkage stress
associated with this method are not known to be
responsible for cusp deformation or deflection in
posterior restorations [17, 46, 92], despite the fact
that these materials demonstrate volume shrinkage of
3 to 3.5% [33]. In comparison, volume shrinkage of
1.9 to 2.3% has been determined for sculptable bulk-
fill composites [56].
Bulk-fill composites show very little shrinkage stress
during polymerization [30, 59]. They exhibit accept-
able deformation behaviour (creep) under loading, in
other words, high dimensional stability, which is com-
parable to that of conventional composites. These
properties are fundamental to producing long-lasting
restorations and restoration margins that will with-
stand the conditions in the oral cavity [32].
Bulk-fill composites and the corresponding adhesive
systems can be used to effectively seal cavity floors,
which considerably helps to prevent postoperative
sensitivity in patients [46]. Correctly used, bulk-fill
composites will produce restoration margins that are
just as tight as those of restorations placed with regu-
lar layering composites [4, 16, 46, 88, 107, 112, 117].
In a laboratory study on the marginal adaptation of
Class II restorations, the results of both low-viscosity
and high-viscosity bulk-fill composites were compara-
ble to those of conventional composites [16].
24
Concerns about insufficient microhardness have been
raised with regard to certain products [27]. However,
only the flowable type of bulk-fill composites are
affected, and these materials should be covered with
an occlusal increment of a posterior hybrid composite
in any case [57].
High-performance curing lights should be used and
the polymerization times indicated by the manufacturer
must be observed in order to obtain reliable curing
results at the bottom of 4-mm layers [5, 11, 25, 30, 31
, 47, 48, 60, 69, 106, 130]. A correlation is known to
exist between the monomer conversion rate of a
composite and the material's clinical wear resistance
[38]. In occlusal load-bearing areas, therefore, the
conversion rate of a dimethacrylate-based composite
should not be below 55% [114]. The conversion rate
of double bonds during the polymerization of bulk-fill
composites is comparable to that of conventional
hybrid composites [6,75]. Bulk-fill composites show a
significantly higher double bond conversion rate at the
bottom of 4-mm thick layers compared with regular
composites. This is due to the excellent light trans mission
properties of bulk-fill composites, which enhances the
polymerization of thick increments [48]. Bulk-fill
composites are comparable to their conventional
counterparts in terms of their biocompatibility [40].
A comparison of composite categories rather than
individual materials reveals that high-viscosity bulk-fill
composites have a similar modulus of elasticity to
traditional hybrid composites, which is considerably
higher compared to that of low-viscosity bulk-fill
composites [64]. With regard to the Vickers hardness
and the modulus of indentation, high-viscosity bulk-
fill composites show the significantly highest values,
followed by those of the microhybrid and nanohybrid
composites. Low-viscosity bulk-fill composites exhibit
lower hardness values than traditional flowable
composites [12,64].
Table 7 provides a summary of the mechanical
properties of bulk-fill composites.
Table 7: Mechanical properties of bulk-fill composites (Data from [57] and the latest evaluations based on the data compiled by Prof. D. Ilie, Munich Dental Clinic): Three-point bending strength (σ), elastic modulus (Emodulus) and Vickers hardness (HV). Superscripts identify significant subgroups (Tukey’s HSD Test, α = 0.05). The low-viscosity bulk-fill composites are shown in the grey shaded part of the table.
Tetric EvoCeram Bulk Fill
Bulk-fill composites
120,8a (12,7)
σ (MPa)
4,5AB (0,8)
Emodulus (GPa)
78,4C (6,7)
HV (N/mm²)
Filtek Bulk Fill Flowable Restorative 122,4a (9,6) 3,8A (0,4) 48,4B (1,3)
Venus Bulk Fill 122,7a (6,9) 3,6A (0,4) 38,1A (11,8)
SDR 131,8ab (5,8) 5,0BC (0,4) 54,2B (1,9)
x-tra fil 137,0b (14,4) 9,5E (0,6) 133,5D (32,0)
x-tra base 139,4b (7,0) 6,0CD (0,9) 85,1C (11,2)
SonicFill 142,8b (12,9) 6,9D (0,6) 82,0C (4,7)
QuiXfil 138,6b (20,5) 8,7E (2,6) 126,1D (19,6)
25
3.3 Light transmission of bulk-fill composites
Various mechanisms are responsible for improving the
depth of cure of the different bulk-fill composites.
Nevertheless, enhanced translucency compared with
conventional composites is the common characteristic
of most bulk-fill composites. The light transmission
properties of dental composites determine the way in
which the materials have to be polymerized. Research
studies confirm that regular composites [95, 96] as
well as bulk-fill composites [39, 60, 62, 63] exhibit a
material-dependent sensitivity to variations in light
under simulated clinical conditions.
Under ideal laboratory conditions, less than
200 mW/cm² irradiance could be measured at the
bottom of 2-mm thick layers of regular nanohybrid
composites after curing with a high-performance
polymerization light (1,650 mW/cm²). Furthermore, it
was found that hardly any light could penetrate
through 4-mm layers. With regard to 6-mm
increments, some composite materials were shown to
be completely impenetrable (Table 8).
The energy density of light in the absorption
spectrum of the photo-initiators of dental composites
(360 – 540 nm), which penetrates 2-mm and 4-mm
increments is significantly higher in bulk-fill composites
than in regular composites: This raises the probability
of an adequately cured material in thicker increments.
SonicFill represents an exception in this category, in
that its translucency is similar to that of conventional
composites (Table 8).
A direct comparison of bulk-fill composites with the
corresponding microhybrid and nanohybrid compos-
ites of the same manufacturer reveals the different
composition strategies of bulk-fill composites.
The most striking difference exists between Venus
Diamond and Venus Bulk Fill. Six-mm thick layers of
the highly translucent bulk-fill composite have better
light transmission properties than 2-mm increments
of the nanohybrid composite (Figure 1).
Tetric EvoCeram Bulk Fill also exhibits a higher
translucency than the conventional Tetric EvoCeram.
Nevertheless, the difference in this case is not as
dramatic. The lower translucency of the material,
which enables Tetric EvoCeram Bulk Fill to blend in
more smoothly with the posterior dentition, without
showing the greyish tinge otherwise associated with
this materials group, is effectively compensated by
the new and very sensitive Ivocerin light initiator
system [51,71]. Due to its high absorption rate in the
visible light range, Ivocerin demonstrates enhanced
quantum efficiency and high light reactivity [94].
Therefore, composite layers can be cured to a relatively
deep level with a lower photon density [15].
26
x-tra base
GrandioSO
SDR
Premise
Venus Bulk Fill
Tetric EvoCeram
Filtek Bulk Fill Flowable Restorative
Venus Diamond
x-tra fil
CeramX mono+
SonicFill
Clearfil Majesty Flow
Tetric EvoCeram Bulk Fill
GrandioSO Heavy Flow
Table 8: Light transmittance [12] (360 – 540 nm) of different materials, measured at the bottom of 2, 4 and 6-mm thick layers. Superscripts identify significant subgroups (Tukey’s HSD Test, α = 0.05). The initial irradiance (light intensity of the curing device at the surface of the test specimen) was 1,650 mW/cm².
27
Composite
Low-viscositybulk-fill
High-viscositybulk-fill
Nanohybrid
Flowable
262,5E (8,2) 79,2e (4,1) 27,7E (4,2)
157,7H (12,3) 22,7j (2,5) 5,2G (4,3)
410,3B (5,7) 167,8b (6,4) 73,7B (2,7)
55,4K (3,1) 1,7l (3,5) 0,0H (0,0)
711,4A (13,9) 354,6a (10,6) 202,7A (10,5)
183,7G (11,0) 35,1i (1,8) 14,0F (11,3)
220,4F (6,9) 56,3f (1,4) 18,3F (1,8)
193,1G (15,5) 39,6h (4,5) 6,5G (5,5)
370,3C (11,1) 124,1c (2,0) 53,8C (3,7)
138,7I (6,4) 20,7j,k (1,3) 0,0H (0,0)
118,8J (14,1) 19,1k (2,8) 0,0H (0,0)
222,7F (20,3) 44,3g (3,5) 6,1G (5,1)
317,9D (15,3) 110,8d (2,6) 40,7D (4,1)
164,1H (11,1) 21,6j,k (0,9) 0,0H (0,0)
Figure 1: Comparison of the light transmittance of bulk-fill composites and that of conventional composites of the same manufacturer:a) Heraeus Kulzer; b) Ivoclar Vivadent.
2 mm 4 mm 6 mm
Type of compositeIrradiance mW/cm²
a b
Tetric EvoCeram Bulk Fill
Tetric EvoCeram
Thickness, mma
Venus Bulk Fill
Venus Diamond
Thickness, mm
Lig
ht
tran
smit
tan
ce, m
W/c
m2
b
Lig
ht
tran
smit
tan
ce, m
W/c
m2
Thickness, mm
3.4 How much light do bulk-fill composites need
to polymerize adequately?
An in vitro study has established that the conversion
rate and the mechanical properties of bulk-fill
composites remain constant at depths of 4 and 6 mm
if the material is sufficiently light polymerized [25].
Under clinical conditions, however, the full amount of
light which is used to polymerize a composite does
not always reach the restoration due to problems
related to accessing the restoration in tight areas
of the oral cavity or the angle of the light guide,
particularly in posterior dentition. Consequently, only
a part of the light dose is available for polymerization
purposes. Nevertheless, excessively long poly-
merization intervals using high light intensity should
also be avoided to prevent thermal pulp damage
[8, 10, 65, 98, 129].
Therefore, it is important to find out how tolerant
bulk-fill composites are towards different light doses
and to establish certain limits which will nonetheless
produce good polymerization results. To date, efforts
to precisely quantify the amount of light needed to
polymerize bulk-fill materials have been made in only
two studies, which were performed under simulated
clinical conditions [62, 63]. It is generally accepted
that the maximum depth of cure of a composite
under specific polymerization conditions is obtained
when 80% of the hardness measured at the top of
the increment is measured at the bottom of the layer
[5, 22, 41, 74, 104, 116]. This increment is considered
to be adequately polymerized. Table 9 shows the
maximum depth of cure of high-viscosity bulk-fill
composites obtained under various polymerization
conditions (different curing modes of the polymeriza-
tion light, 0 vs 7 mm distance of the light guide to the
composite surface).
28
Table 9: Maximum depth of cure (in mm) as a function of the polymerization conditions and the material [62]. LED polymerization light VALO (Ultradent Products Inc., South Jordan, UT, USA). Superscripts identify significant subgroups (Tukey’s HSD Test, σ α = 0.05). The significantly highest mechanical properties were obtained at depths greater than 2 mm with polymerization intervals of 20 and 40 s (Standard Pow-er mode / 1,176 mW/cm2) for both light-curing distances (0 and 7 mm), which was reflected by a high depth of cure. In a few cases, the above-mentioned polymerization conditions were equivalent to a light exposure time of 8 s (High Power mode / 1,766 mW/cm2) or 6 s (Plasma / 3,416 mW/cm2). Shorter polymerization intervals (5 s Standard Power mode, 3 – 4 s High Power mode, and 3 s Plasma) resulted in a shallower depth of cure. The light intensity of the polymerization light used (VALO) was measured with a spectrometer (USB4000 Spectrometer, Managing Accurate Resin Curing System; Bluelight Analytics Inc., Halifax, Canada).
29
5s Standard 5,88 3,7DE(0,11)
0
4,5bcde (0,54) 2,7cdef(0,30)
6s Plasma 20.50 5,7IJ(0,27)5,8f (0,26) 4,0hi(0,09)
20s Standard 23,51 5,6IJ(0,46)6,0f (0,00) 4,3i(0,23)
5s Standard 3,23 2,7AB(0,30)
7
3,0a (0,65) 2,2abc(0,14)
40s Standard 47,03 6,0J(0,00)6,0f (0,00) 5,4k(0,38)
20s Standard 12,93 5,3HI(0,23)5,9f (0,12) 3,9hi(0,23)
3s High 5,30 3,2BCD(0,20) 3,7abc (0,58) 2,2abcd(0,17)
40s Standard 25,85 5,9J(0,27)6,0f (0,00) 4,8j(0,22)
4s High 7,06 3,4CD(0,22)4,4bcd (0,45) 2,7def(0,18)
3s High 2,63 2,4A(0,26)2,9a (0,90) 1,8a(0,22)
3s Plasma 5,25 3,2BCD(0,17) 3,8abc (0,30) 2,5bcde(0,11)
8s High 14,13 4,9GH(0,27)4,7cde (0,50) 3,6gh(0,26)
4s High 3,50 2,9ABC(0,27)3,6ab (0,59) 2,2ab(0,26)
6s Plasma 10,50 4,4FG(0,36)5,5def (0,38) 3,8hi(0,20)
3s Plasma 10,25 4,2EF(0,22)4,9def (0,64) 3,0ef(0,09)
8s High 7,00 4,2EF(0,28)5,6ef (0,49) 3,2fg(0,17)
Vickershardness
reference value47,03 78,4c(6,7)0 133,5a(32,0) 89,4b (10,1)
Energy (J/cm²)at samplesurface
Polymeriza-tion mode
Distance (mm)between ight guide and sample surface
Depth of cure (mm)
x-tra fil TetricEvoCeramBulk Fill
Sonic Fill
4.1 Published clinical studies
The best reference for a composite is its clinical long-
term performance in the patient's mouth. The limited
data that has come out of clinical studies on bulk-fill
composites to date reveals satisfactory to very good
intraoral performance [19, 43, 66, 84, 85, 123]. A three-
year clinical evaluation by VAN DIJKEN did not report
any failures in restorations placed with the flowable
material SDR in combination with the nanohybrid
composite CeramX mono. The reference composite
used showed an annual failure rate (AFR) of 1.3%
[123]. In a user study involving dental practitioners,
68 restorations placed with Tetric EvoCeram Bulk Fill
were evaluated after one year in situ. Only one
restoration fracture (AFR = 1.5%) was recorded.
Apart from this failed restoration, the clinical
properties were deemed to be excellent [3]. In a
clinical study on Tetric EvoCeram Bulk Fill, all the
posterior restorations were given mostly excellent
ratings after an observation period of one year. None
of the restorations had to be replaced [103]. After
one year in situ, YAZICI did not determine any
significant differences between restorations placed
with Tetric EvoCeram Bulk Fill and the nanocomposite
Filtek Ultimate [120]. GREGOIRE reported excellent
clinical performance of Tetric EvoCeram Bulk Fill
restorations after one year in a comparison with
incrementally placed posterior restorations using
Gradia Direct [120]. Data gathered by our working
group in Munich showed that the clinical perfor-
mance of the high-viscosity bulk-fill composite QuiXfil
(placed in 4-mm increments) did not differ significantly
from the traditional hybrid composite Tetric Ceram
(placed in 2-mm increments) after four years [85].
After an observation period of ten years, QuiXfil
demonstrated an annual failure rate of 1.8%. The
AFR of Tetric Ceram of 1.5% was not significantly
different [87].
Bulk-fill composites do not consitute a uniform class
of materials. Considerable differences exist between
the individual products with regard to the composition
and the size of the filler particles. In order to achieve
a depth of cure of 4 mm, some manufacturers simply
reduce the filler content or use larger particles in their
bulk-fill composites. This allows light to penetrate
more deeply into the material during polymerization.
However, this strategy has its drawbacks: negative
influence on the mechanical and esthetic properties,
increase in the surface roughness and reduction of
the wear resistance [23, 24, 64]. No such compromises
were made in the formulation of Tetric EvoCeram
Bulk Fill. This advanced bulk-fill composite is based on
the monomer composition and filler technology of the
clinically proven universal composite Tetric EvoCeram.
In addition, Tetric EvoCeram Bulk Fill features an
innovative photo-initiator called Ivocerin, which is
highly reactive to incoming photons and therefore
enables the restorative material to cure to a depth of
4 mm. In contrast to many other bulk-fill composites,
Tetric EvoCeram Bulk Fill contains comparatively small
fillers. Consequently, its surface is very smooth and
easy to polish to a high gloss finish. Furthermore, the
composite shows good wear resistance and esthetic
properties.
4. Clinical data
30
31
Figure 1
Three-surface amalgam restoration
in an upper first molar
Case 2:
Replacement of an amalgam restoration
in an upper molar
The second case shows how an esthetic
Tetric EvoCeram Bulk Fill restoration was placed
and then polished to a high-gloss finish.
Initial situation
Figure 2
Situation after the removal of
the old restoration
Figure 4
The tooth structure was conditioned with
Adhese Universal using the self-etch technique
(reaction time 20 s)
Figure 3
After excavation and fine-grit finishing,
a rubber dam was placed to create a dry
working field.
32
Figure 5
Light polymerization of the adhesive
with Bluephase Style for 10 s
Figure 6
The first composite increments
of Tetric EvoCeram Bulk Fill were used
to build up the mesial and distal
proximal walls of the cavity.
33
Figure 7
Light polymerization of the composite
with Bluephase Style for 10 s
34
Figure 8
Once the proximal composite walls
were sufficiently polymerized, the
matrix was removed completely.
Figure 9
Next, both proximal boxes were
filled with Tetric EvoCeram Bulk Fill
up to the isthmus of the cavity.
Figure 10
Light polymerization
of the composite for 10 s
35
Figure 11
Application of Tetric EvoCeram Bulk Fill for
building up the buccal cusps
Figure 12
Sculpting of the buccal cusps
Figure 13
Light polymerization
of the buccal cusps for 10 s
36
Figure 15
Light polymerization of the
palatal cusps for 10 s
Figure 16
View of the restoration after finishing
and the adjustment of the static and
dynamic occlusion
Figure 14
Sculpting of the palatal cusps
37
Figure 17
Finished and high-gloss polished restoration.
The tooth has regained its original appearance and function.
Initial situation
Final situation
Since Tetric EvoCeram Bulk Fill is closely related to
Tetric EvoCeram from the same manufacturer, some
careful predictions regarding the long-term performance
of the bulk-fill material can be made on the basis of
the clinical data available from the literature on
Tetric EvoCeram.
In one clinical study, Tetric EvoCeram showed excellent
wear resistance in occlusal load-bearing posterior
restorations [20]. After an observation period of five
years, CETIN did not establish any significant
differences between direct posterior restorations
placed with Tetric EvoCeram and indirect composite
inlay restorations [21]. The in vivo wear behaviour of
Tetric EvoCeram in posterior cavities after five years
fulfilled the stringent ADA standard for posterior
composites [1] (vertical wear < 50µm/year) [101].
BOECKLER reported an excellent survival rate of
98.8% for Tetric EvoCeram in Class I and II cavities in
molars and premolars after a period of two years [9].
In a three-year clinical trial, PALANIAPPAN established
a 100% survival rate of Tetric EvoCeram in posterior
teeth [100]. BARABANTI also reported a survival rate
of 100% for posterior Tetric EvoCeram restorations
studied in a five-year trial [7]. The findings of
MAHMOUD in a two-year clinical evaluation also
confirmed the excellent clinical performance of
Tetric EvoCeram restorations in posterior dentition
[79]. VAN DIJKEN recorded an annual failure rate
(AFR) of 2.1% for Tetric EvoCeram restorations in
Class II cavities after six years in [122]. These results
correspond to the 2.2% annual failure rate of
composite restorations in posterior teeth which was
published in a comprehensive meta-analysis [83].
The mentioned studies all confirm the excellent
clinical performance of Tetric EvoCeram as a posterior
restorative material. Since Tetric EvoCeram Bulk Fill is
similarly engineered to Tetric EvoCeram, one can
conclude that this bulk-fill composie will perform just
as well as its regular counterpart..
38
Table 10: Comparison of the mechanical properties of various Ivoclar Vivadent composites (Evaluated on the basis of the data compiled by Prof Dr. Ilie, Munich Dental Clinic): Three-point bending strength (σ), elastic modulus (Emodulus) and Vickers hardness (HV). Superscripts identify significant subgroups (Tukey’s HSD Test, α = 0.05).
4.2 Comparison of Tetric EvoCeram Bulk Fill with
other Ivoclar Vivadent composites
In order to further assess the clinical behaviour of
Tetric EvoCeram Bulk Fill, the results of this material
were compared with the in vitro data of nine other
clinically time-tested composites from Ivoclar Vivadent
(Table 10).
With regard to the flexural strength, no statistically
significant difference was established between
Tetric EvoCeram Bulk Fill and the trusted composites
Tetric Ceram, Tetric EvoCeram and Tetric Ceram HB.
The modulus of elasticity of Tetric EvoCeram Bulk Fill,
however, was found to be significantly lower than
that of the other high-viscosity Tetric products.
Nonetheless, the value is within the range of the
IPS Empress Direct Dentin and IPS Empress Direct
Enamel materials. In the Vickers hardness tests,
Tetric EvoCeram Bulk Fill showed significantly higher
values than the regular Tetric EvoCeram. This data
highlights the competitive in vitro properties of
Tetric EvoCeram Bulk Fill in comparison with other
composites from Ivoclar Vivadent. Moreover, on the
basis of a comprehensive analysis of the in vitro data
available today, one can cautiously conclude that the
new bulk-fill composites will be able to hold their own
against regular composites and achieve successful
clinical results, provided that they are used properly
and in accordance with the directions of the
manufacturer [46, 51, 92, 97, 107, 108, 115].
Nevertheless, the clinical behaviour of bulk-fill
composites has to be studied in greater depth and
more evidence needs to be collected [78]. Even though
the demand for more clinical long-term data is
justified, this type of information cannot be supplied
at present. Due to the fact that this type of material is
a recent development, long-range results can only be
expected in the future.
Composite σ (MPa) Emodulus (GPa) HV (N/mm²)
Tetric Ceram 134,7E (10,9) 7,9D (0,9) 82,4F (2,3)
Tetric Ceram HB 122,4CDE (21,1) 6,6C (0,4) 86,0G (3,3)
Tetric EvoCeram 115,3BC (11,3) 6,7C (1,1) 70,9C (3,2)
Tetric EvoCeram Bulk Fill 120,8CDE (12,7) 4,5B (0,8) 78,4E (6,7)
IPS Empress Direct Dentin 132,1DE (13,7) 5,3B (0,9) 73,5D (1,7)
IPS Empress Direct Enamel
Tetric Flow
104,8B (8,5)
118,1BCD (9,9)
4,5B (0,8)
5,1B (0,4)
85,6G (3,1)
50,1B (2,4)
IPS Empress Direct Opal
Tetric EvoFlow
73,8A (5,3)
104,2B (10,2)
2,9A (0,2)
2,8A (0,4)
35,6A (2,9)
37,4A (1,5)
39
Tetric 153,6F (21,2) 9,3E (1,7) 98,0H (4,8)
Bulk-fill composites are primarily used to place direct
restorations in permanent posterior teeth.
The low-viscosity, flowable bulk-fill composites
are approved for the following indications:
• Dentin build-up, i.e. bases of up to 4 mm
per increment in Class I and II cavities
(2-mm capping layer of posterior hybrid composite
is needed)
• Cavity liner:
Lining of the cavity floor and
internal line and point angles as a first
thin layer under direct restoratives in
Class I and II cavities
• Fissure sealant
(no capping layer is needed)
• Small Class I restorations
(no capping layer is needed)
• Undercut blockout
• Core build-ups (no capping layer is needed)
The high-viscosity, sculptable bulk-fill composites
are approved for the following indications:
• Direct restorative for Class I and II cavities (incl.
replacement of cusps)
• Preventive resin restorations
• Core build-ups
• Class V cervical restorations
• Restorations in deciduous teeth
In this context, however, it is important to note that
not every bulk-fill composite available on the market
in the different categories (flowable and sculptable) is
approved for all the mentioned indications by its
respective manufacturer.
5. Indication spectrum of bulk-fill
composites in permanent and
deciduous dentition
40
41
Case 3:
Replacement of a ceramic inlay
in a lower molar
The third case shows how a large restoration with cusp
involvement was placed in a lower first molar using
Tetric EvoCeram Bulk Fill.
Figure 1
Insufficient ceramic inlay in
a lower first molarInitial situation
42
Figure 2
In the past, a large ceramic
restoration was used to replace
the mesio-buccal cusp.
Figure 3
View after the removal of the old restoration,
the excavation and finishing of the cavity and
the placement of the rubber dam
Figure 4
Application of a
circumferential metal matrix
43
Figure 5
Conditioning of the tooth structure
with Adhese Universal using the
self-etch technique (reaction time 20 s).
Figure 6
The cavity has been appropriately conditioned
and shows an even shiny surface.
This seals the dentinal tubules and prevents
postoperative hypersensitivity.
Figure 7
Application of the first composite layer
of Tetric EvoCeram Bulk Fill
44
Figure 8
The first composite increment
was used to build up the mesial proximal wall
and the mesio-buccal contour.
Figure 9
Light polymerization of the composite
with Bluephase Style for 10 s
Figure 10
Next, Tetric EvoCeram Bulk Fill
was applied to create the entire occlusal surface,
and the tooth anatomy was sculpted.
45
Figure 11
Light polymerization of the composite for 10 s.
Figure 12
Situation after the matrix
and the rubber dam were removed
and the restoration was finished
Figure 13
Prepolishing of the composite restoration
with OptraPol silicone polishers
46
Figure 14
High-gloss polishing with an
Astrobrush silcone carbide brush
Figure 15
Final adjustment of the static
and dynamic occlusion
Figure 16
Final situation: Finished
and polished restoration.
The tooth has regained its
original appearance and function.
4747
Figure 17
Mesial view of the outstanding reconstruction
of the tooth with cusp replacement
Initial situation
Final situation
Advantages
It goes without saying that sculptable bulk-fill
composites can also be placed in 2-mm increments
according to the conventional layering technique.
Because of their higher translucency and light
reactivity compared with hybrid composites, these
materials offer more reliable polymerization results:
for example, in the event of unfavourable light curing
conditions as a result of restricted opening of the
mouth, which prevents the light guide of the curing
device from being optimally positioned [60]. At an
increment thickness of 2 mm, the polymerization
shrinkage stress is considerably lower than that of
conventional composites. This has a positive effect on
the restoration, the tooth and the adhesive bond
[34, 51, 59].
Sculptable bulk-fill composites can also be used to
restore deciduous posterior teeth. Due to the size of
these teeth and the dimensions of the lesions, most of
the cavities can be restored with a single layer. This
technique shortens the chair time and is particularly
welcome in the treatment of uncooperative children.
Table 11: Advantages of the restorative technique with bulk-fill composites
Restorative technique with bulk-fill composites
Heightened efficiency due to a fast restorative protocol and the elimination of time-consuming layering ➔ more economical [128]
Easier handling [113]
No time-consuming shade selection
Streamlined logistics ➔ less stock of materials has to be kept
Fewer increments ➔ fewer or no transitions between layers ➔ fewer problems at imperfect boundary surfaces
(voids, gaps) between different composite increments [55] and overall minimization of the risk of entrapping voids.
48
The need for composite-based direct restorative
materials is predicted to grow in the future. There-
fore, high-quality, scientifically tried-and-tested and
clinically documented permanent posterior restorative
materials will be in much demand. The results of an
extensive review have shown that the annual failure
rate of composite restorations in posterior teeth
(2.2%) is not statistically different from that of
amalgam restorations (3.0%) [83]. Minimally invasive
treatment protocols in conjunction with the possibility
of detecting carious lesions at a very early stage are
having a positive effect on the survival rate of this
type of restorations. Nonetheless, a high-quality direct
composite restoration with excellent marginal
adaptation continues to be dependent on a number
of prerequisites: for example, careful placement of
the matrix (if proximal areas are involved), effective
and correct application of the dentin adhesive,
appropriate handling of the restorative material and
sufficient curing of the composite.
The growing economic pressure on the health system
and a lack of financial means on the part of patients
are creating a need for reliable, fast and easy-to-use
restorative options as an alternative to the time-
consuming high-end solutions (polychromatic multi-
layer composite restorations bonded with a dentin
adhesive in conjunction with an etch-and-rinse
protocol involving preliminary enamel and dentin
etching with phosphoric acid). In addition to the
universal hybrid composites, which are available in
various shades and levels of opacity, new bulk-fill
composites have lately emerged on the market. They
are designed for use in posterior dentition, where
they produce esthetically pleasing restorations. The
placement procedure is more economical than that of
conventional hybrid composites [14, 84].
49
6. Outlook
51
Figure 1
Fractured amalgam restoration and worn
composite restoration in the lower posterior teeth
Case 4:
Replacement of two insufficient restorations
in the lower posterior dentition
The fourth case shows how a composite and an amalgam
restoration were replaced in the lower posterior dentition
using Tetric EvoCeram Bulk Fill
Initial situation
52
Figure 2
View after the removal of
the old composite restoration and the
excavation of the caries in the first molar
Figure 3
After the finishing procedure
a dry working field was created with a rubber dam.
Figure 4
Application of a
sectional matrix
53
Figure 5
Selective enamel etching
with phosphoric acid for 30 s.
Figure 6
Conditioning of
the tooth structure with Adhese Universal
using the selective-etch technique (reaction time 20 s)
Figure 7
The adhesive was dispersed with air
until a shiny, immobile film
formed.
54
Figure 8
Light polymerization of the adhesive
with Bluephase Style for 10 s
Figure 9
The cavity has been appropriately conditioned
and shows an even shiny surface. This seals
the dentinal tubules and prevents
postoperative hypersensitivity.
Figure 10
The first two composite increments of
Tetric EvoCeram Bulk Fill were used to
build up the mesial and distal proximal cavity walls.
The composite material was shaped with
a clean microbrush.
55
Figure 11
Light polymerization of the composite
with Bluephase Style for 10 s
Figure 12
Reconstructed proximal walls
before the matrix was removed
Figure 13
Once the proximal composite walls
were sufficiently polymerized
the matrix system was removed completely.
As a result, the operating field became more easily
accessible with modelling instruments for
the following working steps.
56
Figure 14
First, the Class II cavity
was transformed into a
functional Class I cavity.
Figure 15
Next, the two proximal boxes
were filled with
Tetric EvoCeram Bulk Fill
up to the isthmus of the cavity.
Figure 16
Application of Tetric EvoCeram Bulk Fill
to build up the remaining portion of the cavity
57
Figure 17
Sculpting of the occlusal anatomy
Figure 18
A clean microbrush was used
to adapt the composite
to the marginal areas. The composite does
not stick to the "filling instrument".
Figure 19
Light polymerization
of the occlusal layer for 10 s.
58
Figure 20
Once the restoration in the first molar was completed,
the fractured amalgam restoration in the second
premolar was replaced with Tetric EvoCeram Bulk Fill.
Figure 21
View of the restorations after finishing
and the adjustment of the static and
dynamic occlusion
Figure 22
Final situation: Finished and high-gloss
polished restorations. The teeth have regained
their original function and appearance.
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